KR101483837B1 - Plate heat exchanger plate and plate heat exchanger - Google Patents

Abstract

A first field 30 having first corrugations substantially aligned with one side of the first line 26 intersecting the second side edges 6a and 6b and a second field 30 having first corrugations, There is provided a plate heat exchanger plate (2) having a main heat transfer portion (14) including a first region (16) including a second field (32) with second corrugations substantially arranged on the plate. The main heat transfer portion 14 includes a first outer region 18 arranged between the first region 16 and a first second side edge 6a of the second side edges, 1 and the second dispensing portions 12a, 12b along the first second side edge 6a. In the first outer region 18, a plurality of first side edges 4a, 4b are oriented in a first overall direction with respect to a second straight line 27 parallel to a first side edge of one of the first side edges 4a, The first projections and recesses are arranged. Thereby, when the corrugations in the first region 16 are directed in different directions, a plate 2 with a straight first second edge 6a can be provided.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plate type heat exchanger plate and a plate type heat exchanger,

The present invention relates to a plate-type heat exchanger plate according to the preamble of claim 1 and a plate-type heat exchanger including such a plate.

Plate heat exchangers having plate packages of plate heat exchanger plates are used to exchange heat between two or more heat exchange fluids. The plates form interplate spaces configured to flow through the heat exchange fluids. The plates have port holes, and such port holes form channels extending through the plate package. In the case of heat exchange between the two heat exchange fluids, each channel communicates for every second interplate space. The first heat exchange fluid flows from the first channel through each alternate interplate space through the heat exchange surfaces of the plates to the second channel at the opposite end of the plate package. The second heat exchange fluid flows from the third channel through every other alternate interplate space through the heat exchange surfaces on opposite sides of the plates to the fourth channel at the opposite end of the plate package. Heat exchange fluids may be, for example, gases, liquids, liquids containing solid material, and the like.

The heat exchange surfaces of the heat exchange plates have pleats. These wrinkles may have many different shapes, but generally include raised and lowered portions. The pleats may define the width of the spaces between the plates, create turbulent flow within the spaces between the plates, and serve as supports for adjacent plates in the plate package. Generally, the plates are made from sheet metal, and such sheet metal has wrinkles in one or more pressing operations.

There are various different wrinkle patterns used for heat exchange plates. One wrinkle pattern type includes first ridges and grooves arranged in a first direction and second floors and grooves arranged in a second direction so that a V-shape similar to a herringbone pattern is formed, A pattern of features is formed in at least some portions of the plate.

Because the sheet metal material is displaced during the pressing operation when the V-shaped pattern of corrugations including floors and grooves points in the direction from the edge of the plate toward the center of the plate, . Also, if the V-shaped pattern is arranged close to the plate edge and narrows in the other direction, the relevant edge portions can be affected. In addition to being visually unfavorable, deformed edge portions can cause weak edges of the plate. In particular, plate heat exchangers having gaskets arranged between the plates must have strong and stable edge portions in order to prevent leakage of the plate heat exchanger. In order to prevent weak edges, sheet metal blanks for manufacturing heat exchanger plates must be cut larger than in the case of heat exchanger plates having other corrugated patterns. Thus, the utilization of sheet metal materials is not optimized.

International Patent Publication WO94 / 19657 discloses such a heat exchanger plate in which several of the aforementioned V-shaped patterns are narrowed towards the center of the plate and towards the edges of the plate.

It is an object of the present invention to provide plate heat exchanger plates with uniformly displaced edges, thereby allowing a design in which the sheet material can be efficiently utilized for heat transfer purposes.

According to an aspect of the present invention, the object is achieved by delimiting by two substantially parallel first side edges and two substantially parallel second side edges, 1 plate-like heat exchange with port holes proximate to the dispensing portion, port holes adjacent the second dispensing portion at the second end of the plate, and a main heat transfer portion including a pleat pattern between the first dispensing portion and the second dispensing portion Lt; / RTI > The main heat transfer portion includes a first field having first corrugations substantially aligned on one side of a straight first line intersecting the second side edges and a first field substantially on the opposite side of the first line, And a second area having second corrugations arranged therein. The first corrugations include floorings and grooves oriented at an angle between 0 and less than 90 degrees with the first line when measured in a clockwise or counterclockwise angular orientation. The second corrugations include floors and grooves oriented at an angle between greater than 270 and less than 360 angles to the first line when measured in the angular direction. Wherein the main heat transfer portion comprises a first outer region arranged between the first region and a second side edge of a first one of the second side edges and wherein a first portion between the first and second distribution portions Extend along two side edges. In the first outer region, first protrusions and recesses oriented in a first general direction with respect to a second linear line parallel to the first side edge of one of the first side edges are arranged in an array do.

Since the first outer region includes first protrusions and recesses oriented only in the first overall direction, the portion of the main heat transfer portion including pleats that can displace portions of the sheet material forming the plate during the pressing operation Regardless of area 1, the first, second side edge is uniformly influenced during the pressing operation. As a result, the above-described object is achieved. A linear edge relatively close to the main heat transfer portion is achieved. Thus, more of the plate can be used for heat transfer than if the plate did not have a first outer region of the kind described above.

The protrusions and recesses form the corrugations of the heat exchange plate and may have other shapes such as single tips and dimples or floors and grooves. In any case, the protrusions and recesses form a pattern that can be seen to have an orientation. The protrusions and recesses in the first outer region are directed only in the first overall direction with respect to the second line. The overall direction associated with the second line is that the direction of the protrusions and recesses may be different in different parts of the outer region but that the overall direction in the other parts is the same, .

According to exemplary embodiments, the main heat transfer portion may include a first outer region and a second outer region disposed between a second one of the second side edges, And extending along a second second side edge of the second side edges between the first and second dispensing portions, and wherein in the second outer region, Oriented second protrusions and recesses are arranged. In this manner, a second second side edge of the second side edges may also be maintained in a straight line during manufacture of the heat exchanger plate.

According to exemplary embodiments, the first region is substantially arranged on one side of the first line and is substantially arranged on the first side of the floor and grooves oriented at an angle between greater than 90 and less than 180 degrees from the first line in the angular direction A third field having a third corrugation and a floor and grooves substantially oriented on the opposite side of the first line and oriented at an angle between greater than 180 and less than 270 angles from the first line in an angular direction The fourth field having a fourth corrugation. The plate comprising such third and fourth fields would have V-shaped pleated formations that narrowed from both sides toward the center of the plate so that from the outer regions arranged along both of the second sides, You can take advantage of this.

According to exemplary embodiments, the floors and grooves of the first corrugations may be oriented at an angle between the first line and an angle of greater than 45 and less than 90 with respect to the first line when measured in the angular direction, and the floor of the second corrugations And grooves may be oriented at an angle between the first line and an angle greater than 270 and less than 315 when measured in the angular direction. The floors and grooves of the first and second pleats with these specified angles form a pleated pattern in which the heat exchange fluid is subjected to a relatively low flow resistance. During the pressing operation, the floors and grooves of the first and second pleats with these specified angles are particularly susceptible to displacing the sheet material forming the plate and can take advantage of one or more outer regions on the main heat transfer portion have.

According to exemplary embodiments, the floors and grooves of the third corrugations may be oriented at an angle between the first line and an angle greater than 90 and less than 135 degrees when measured in an angular direction, and the floor of the fourth corrugations And grooves may be oriented at an angle between the first line and an angle greater than 225 and less than 270 when measured in the angular direction. During the pressing operation, the floors and grooves of the third and fourth pleats with these specified angles again tend to displace the sheet material forming the plate in particular, and take advantage of the second outer region on the main heat transfer portion .

According to exemplary embodiments, the first overall direction and / or the second overall direction may comprise one or more angles between 0 and less than 90 degrees with respect to the second line. The first and second overall directions may be the same direction, or the directions may be directed differently.

According to exemplary embodiments, the first outer region and / or the second outer region may have a measured width parallel to the second line, such width being narrower than the first field measured parallel to the second line . Accordingly, the first and second outer regions can form peripheral regions of the main heat transfer portion.

According to exemplary embodiments, the first and / or second protrusions and recesses in the first outer region and / or the second outer region may include corrugations and grooved pleats.

According to exemplary embodiments, in the first and second outer regions, when measuring across floors and grooves, the floors may have different widths than the grooves. For example, all floors may be wider than all floors, or all floors may be narrower than all floors. In this manner, different flow resistances can be created for the heat exchange fluid flowing in the space between the plates between the two plate heat exchanger plates. Accordingly, a uniform distribution of the heat exchange fluid over the entire main heat transfer portion can be promoted.

According to exemplary embodiments, the first projections and recesses may be oriented in a first direction relative to the second line, and / or the second projections and recesses may be oriented in relation to the second line Can be oriented in two directions. Accordingly, the protrusions and recesses in the first outer region can be oriented in only one direction with respect to the second line. Likewise, accordingly, the protrusions and recesses in the second outer region can be oriented in only one direction with respect to the second line. In this way, the plate will be uniformly influenced close to the second side edges while forming the plate in one or more pressing operations.

According to exemplary embodiments, the first side edges can be short sides and the second side edges can be long sides of the plate.

According to exemplary embodiments, the first outer region and / or the second outer region may be divided into two or more fields. This can stabilize the large plate heat exchanger plate.

According to an aspect of the invention, there is provided a plate heat exchanger comprising a plate package of plate heat exchanger plates according to any of the aspects or exemplary embodiments described above.

According to exemplary embodiments, the plate heat exchanger plates may be alternately arranged in the plate package such that the first outer region of one plate contacts the second outer region of the plate in contact therewith. In this way, the interplate spaces between the plates in the areas of the outer areas can be defined by the other outer areas of the two contact plates. In the exemplary embodiments, in forming the plate package, only one type of plate-type heat exchanger plate may be required.

According to exemplary embodiments, the plate heat exchanger may be configured for substantially parallel flow of at least two heat exchange fluids over the main heat transfer portion of the plates in the plate package.

Additional features of the invention and additional advantages thereof may be apparent from the appended claims and the following description. It will be understood by those skilled in the art that various features of the invention may be combined with other embodiments than those described below without departing from the scope of the present invention as defined in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS Various aspects of the invention, including particular features and advantages thereof, may be readily understood from the accompanying drawings and the following specific description.
Figures 1 and 2 are schematic views of plate heat exchanger plates according to exemplary embodiments.
3 is a schematic cross-sectional view through portions of a plate heat exchanger plate package.
Figure 4 shows a plate-type heat exchanger according to exemplary embodiments.

The present invention will now be described more fully with reference to the accompanying drawings, in which: Fig. However, the present invention should not be construed as limited to the embodiments described herein. As will be readily appreciated by those skilled in the art to which this invention belongs, the disclosed features of the exemplary embodiments can be readily combined. Throughout the Figures, like numbers represent like elements.

For brevity and / or clarity, well-known functions or constructions will not be described in detail.

Figure 1 schematically shows a plate-type heat exchanger plate 2 according to exemplary embodiments. Several such plates (2) are arranged in a plate heat exchanger plate package. The plate-type heat exchanger is arranged for heat exchange between two heat exchange fluids when two fluids flow through an alternate interplate space formed between the plates 2. The plate 2 is substantially rectangular and has two first side edges 4a and 4b forming a short side of the plate 2 and two second side edges 4a and 4b forming a long side of the plate 2. [ (6a, 6b). The plate 2 has four port holes 8a, 8b and 10a, 10b. Port holes 8a, 8b, 10a, 10b form four channels extending through the plate package. Two of the channels communicate with the spaces between every second plate, and the other two channels communicate with the spaces between the remaining plates. In use, the first heat exchange fluid will flow from the one side of the plate 2 through the first port hole 8a to the second port hole 8b, and the second heat exchange fluid will flow from the other side of the plate 2 Will flow between the third port hole 10a and the fourth port hole 10b from above. Thereby, heat from one of the heat exchange fluids is transferred through the plate 2 to another heat exchange fluid.

Referring to the visible side of the plate 2 of Figure 1, a first dispensing portion 12a is provided in relation to the first port hole 8a. With respect to the second port hole 8b, a second dispensing portion 12b is provided. Between the first distribution portion 12a and the second distribution portion 12b, the main heat transfer portion 14 is arranged. In use, the first distribution portion 12a serves to distribute the associated fluid across the width of the main heat transfer portion 14. [ As a result, the second distribution portion 12b serves to funnel the fluid from the main heat transfer portion 14 to the second port hole 8b. The dispensing portions 12a, 12b have a corrugation pattern that can provide for effective dispensing and dispensing of heat transfer fluids.

On opposite sides of the plate 2 are provided dispensing portions associated with the third and fourth port holes 10a, 10b. In use, these dispensing portions, although related to other heat exchange fluids, have the same function as the first and second dispensing portions 12a, 12b.

The plate 2 has gasket grooves, and such gasket grooves are configured to receive one or more gaskets. When one or more gaskets are arranged in the gasket grooves between the two contact plates 2, the gasket (s) border the port holes, the distributing portions and the main heat transfer portion from the ambient atmosphere, and in use, To seal the space between the plates and the channels formed by the heat exchange fluid to prevent leakage of heat exchange fluids. Accordingly, in view of the contents shown in FIG. 1, the first and second port portions 8a and 8b, the first and second distribution portions 12a and 12b, and the main heat transfer portion 14, One gasket 15 is located in the gasket groove surrounding the region. Further, the gasket 15 is arranged around each of the third and fourth port holes 10a, 10b. Instead, independent gaskets can be used around each of the third and fourth port holes 10a, 10b.

The main heat transfer portion 14 includes a first region 16 arranged between three primary regions, i.e., a first outer region 18 and a second outer region 20. The first region 16 includes several fields with corrugations including ridges and grooves oriented in different directions. In this example, there are twelve such fields in the first area 16 highlighted as continuous lines. The first outer region 18 extends along the first edge 6a of the second side edges between the first and second distribution portions 12a and 12b and has three fields 22a, 22c. The second outer region 20 extends along the second edge 6b of the second side edges between the first and second distribution portions 12a and 12b and has three fields 24a, 24c.

Will be described taking a closer view in the direction of the floors and grooves of the fields of the first region 16. For purposes of illustration, a straight first line 26 intersects the two second side edges 6a, 6b. A first field (30) is arranged on one side of the first line (26). When measured clockwise, the floors and grooves in the first field 30 are oriented at an angle of about 60 degrees with the first line 26. The second field 32 is arranged on the opposite side of the line 26. When measuring in the same direction as the floorings and grooves in the first field 30, the floorings and grooves in the second field 32 are oriented at an angle of about 300 degrees with the first line 26. On the side of the first line 26, which is the same as the first field 30, the third line 26, which has the floorings and grooves oriented at an angle of about 120 degrees with the first line 26, Field 34 is arranged. On the side of the first line 26, which is the same as the second field 32, there is provided a second line 32, which, when measured again in the same direction as before, Four fields 36 are arranged.

The first and second outer regions 18, 20 have protrusions and recesses. In this embodiment, the protrusions and recesses are formed as floors and grooves similar to the corrugations in the first region 16. Within the outer regions 18,20, the floors and grooves all have the same general direction in the three fields 22a-c, 24a-c. Within the first outer region 18, the floors and grooves in the middle field 22b have slightly different angles from the two surrounding fields 22a, 22c. Similarly, in the second outer region 20, the floors and grooves do not all have the same direction in the three fields 24a, 24b, 24c. However, in all three fields 22a-c, 24a-c of the first and second outer regions 18,20, both the floors and grooves have the same overall direction, And the angles of the grooves are within 0 to 90 degrees of the second straight line 27 parallel to the first side edge 4a of one of the first side edges.

In one or more pressing operations in which the plate 2 is made from sheet metal, the plate material is moved by the corrugations, i. E. During pressing, the plate material can be displaced to at least some extent. The corrugations in the first and second fields 30 and 32 form a V-shaped pattern pointing from the first second side edge 6a toward the middle of the plate 2. [ In the region of this V-shaped pattern, the plate material can be moved toward the middle of the plate 2. [ Due to the first outer field 18 arranged between the first region and the first second side edge 6a, the first second side edge 6a will be uniformly influenced in the pressing operation.

In other parts of the plate 2, the material may be displaced in different directions during the pressing operation. However, the first and second outer fields 18,20 ensure that the second side edges 6a, 6b are uniformly displaced along the main heat transfer portion 14 of the plate 2 during the pressing operation will be. Thus, the second side edges 6a, 6b of the plate 2 will remain substantially even after the pressing operation.

Figure 2 schematically shows a plate-type heat exchanger plate 2 according to exemplary embodiments. In schematic layout and function, the plate 2 corresponds to the plate 2 shown in Fig. The key difference between the two plates is the first region 16 of the main heat transfer portion 14 of the plate. The corrugation patterns of the floors and grooves in the first region 16 of Fig. 2 are configured differently from those of Fig.

The first region 16 includes several fields, wherein the corrugations and grooves of the corrugations are directed in different directions. The first straight line 26 intersects the second side edges 6a, 6b of the plate 2. [ A first field 30 is arranged on one side of the first line 26. When measured clockwise, the floors and grooves in the first field 30 are oriented at an angle of about 40 degrees with the first line 26. A second field 32 is arranged on the opposite side of the line 26. When measured in the same direction as the floors and grooves in the first field 30, the floors and grooves in the second field 32 are oriented at an angle of about 320 degrees with the first line 26. The corrugations in the first and second fields 30,32 are narrowed from the first second side edge 6a of the second side edges toward the second second side edge 6b of the second side edges forming a pointing V-shaped pattern. Again, the first outer region 18 extends along the first second lateral edge 6a between the first and second dispensing portions 12a, 12b, and the second outer region 20 extends along the first, And between the second dispensing portions 12a, 12b along a second second side edge 6b. In this embodiment, each of the outer regions 18,20 comprises a field of ridges and recesses in the form of floors and grooves. The floors and grooves in the first outer region 18 are oriented in only one first direction and the floors and grooves in the second outer region 20 are oriented in only one second direction.

Again, a first outer region 18 and a second outer region 20 having projections and recesses directed in one direction with respect to a straight second line 27 parallel to the first side edge 4a, Each ensure that the second side edges 6a, 6b remain essentially straight when the plate 2 has a corrugated pattern during manufacture.

The first and second outer regions 18 and 20 are narrower than the first field 30 or the second field 32 in a direction parallel to the second line 27, respectively. As such, the first and second outer regions 18, 20 form a portion of the main heat transfer portion 14 that is narrower than the first region 16.

FIG. 3 shows a schematic cross-sectional view through portions of a plate heat exchanger plate package 40. FIG. The portions shown correspond to the portions of the first and second outer regions 18, 20 of the heat transfer plate 2. The plate 2 has floors and grooves with different widths in the first and second outer regions 18,20. In the outer regions 18, 20, for example, all floors may have the same width and all the grooves may have the same width, and the width of the grooves is narrower than the width of the floors. The interplate spaces 42 between the two contact plates 2 will be shaped differently at the other sides of the same interplate space 42, since the floorings and grooves have different widths. Accordingly, the heat exchange fluid flowing through the interplate space 42 will receive different flow resistances at other sides of the same interplate space 42.

In the following, reference will be made to the upper, left and right sides of the plates 2 in the plate package 40. This is purely to facilitate the description with reference to FIG. 3, and is not intended to limit the aspects of the invention in any way. The floors and grooves of each plate 2 are formed differently on the left and right sides. That is, for example, the second plate 2 from the upper end of the plate package 40 forms a first region 18 on its left side and a second outer region 20 on its right side. In the view shown in Fig. 3, the first region 18 has wide floors and narrow grooves, and the second region 20 has narrow floors and wide grooves. The interplate space 42 between the two contact plates 2 is different on the left and right sides of the plate package 40. 3, the second outer region 20 of the upper plate 2 contacts the first region 18 of the second plate 2 from the upper end, for example, The upper plates 2 are arranged. Since the wide floors contact the wide grooves, the flow resistance will be high. As a result, on the right side, the flow resistance between the two top plates 2 is low because the narrow floors come into contact with the narrow grooves.

The plates 2 in the plate package 40 may be of the same kind. The foregoing arrangement of the first and second outer regions 18,20 of the different plates 2 allows each of the plates 2 of the same kind to be alternately arranged at angles of 180 degrees about the vertical axis 44 And rotating it. By arranging the gaskets in an appropriate manner, the channels formed by the inter-plate spaces 42 and the port holes through the plate package 40 are sealed.

1, it is contemplated that heat exchange fluids are intended to flow in parallel on the plates 2, that is, one heat exchange fluid flows between the first and second port holes 8a, 8b, and The other heat exchanged fluid flows between the third and fourth port holes 10a, 10b. In a parallel flow, the distance that the heat exchange fluid must flow through the heat exchanging surface of the plate 2 varies with the width of the plate 2, the shortest distance being the shortest distance to the first and second port holes 8a, 8b And the longest distance extends from the first port hole 8a across the plate 2 to the opposite second side edge 6b such that the second side edge 6b And then across the plate 2 again to the second port hole 8b. Similarly, on the opposite side of the plate, the heat exchange fluid will flow the shortest distance directly between the third and fourth port holes 10a, 10b, and in the case of the longest distance the heat exchange fluid will flow through the third and It will have to traverse the plate twice in the path between the four port holes 10a and 10b. Due to the different flow resistances in each one and the same inter-plate spaces 42, during use, the distribution of heat exchanged fluids within each inter-plate space 42 will be achieved. If a large flow resistance is provided for the shortest path and a small flow resistance is provided for the longest path, then the heat exchange fluid will flow through the entire associated < RTI ID = 0.0 > Will be more uniformly distributed across the surface.

4 shows a plate-type heat exchanger 50 according to exemplary embodiments. The plate heat exchanger 50 includes a plate package 40 of the plates 2 according to any of the above-described exemplary embodiments. Between the plates 2, gaskets (not shown) are arranged. The plate package 40 is arranged in a frame 52 that includes a frame plate 54, a top bar (bar) 56 and a bottom bar 58. The plate package 40 is clamped between the frame plate 54 and the pressure plate 60 by bolts 62 and nuts 64. The frame plate 54 is provided with four openings 66 and each opening extends to a channel formed by the four port holes 8a, 8b, 10a, 10b of the plates 2 of the plate package 40 Lt; / RTI >

As can be understood by those skilled in the art, the exemplary embodiments can be combined. For example, an outer region containing several fields may have one orientation for protrusions and recesses in all fields. It will also be appreciated by those skilled in the art that instead of plate heat exchangers with gaskets, the present invention may be used with plates of other types of plate heat exchangers, such as welded or brazed plate heat exchangers I can understand.

While the invention has been described with reference to exemplary embodiments, many other applications, modifications, and the like will be apparent to those skilled in the art. Other fields within the main heat transfer portion of the plate, e.g., the first and / or outer regions, may be distinguished from one another by the directions of other pleated patterns or pleated patterns. Also, such fields may be separated by dedicated forms in the plate. Each field may be separate or the fields may be separated together into two or more. Also, the plates can be configured for diagonal flow instead of parallel flow of the heat exchange fluid. That is, the heat exchange fluids can be intended to flow across the plate surface between the diagonally arranged port holes at opposite ends of the plates. In such a case, the first and second outer regions of the main heat transfer portions of the plates are formed such that the spaces between the plates adjacent to the first and second outer regions are substantially similar along both of the two second side edges of the plate .

Accordingly, the foregoing is illustrative of various exemplary embodiments, and the invention is not to be limited to the specific embodiments described, but is capable of modifications to the described embodiments, features of the described embodiments As well as other embodiments are intended to be included within the scope of the appended claims.

As used herein, the terms "comprises" or "comprising" are open-ended and include one or more of the described features, elements, steps, components, or functions, and But do not preclude the presence or addition of one or more other features, elements, steps, components, functions, or groups thereof.

As used herein, the term "and / or" includes any or all combinations of one or more associated listed items.

As used herein, the generic abbreviation "for example (eg)" derived from the Latin phrase "exempli gratia" may be used to introduce or specify generic examples or examples of the items previously mentioned, and And there is no intention to limit it to such items. As used herein, the generic abbreviation "i. E." Derived from the Latin phrase "id est" may be used to specify a particular item from a more general citation.

It is to be understood that the technical terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, unless explicitly stated otherwise in the description of the description, "singular form" is intended to include plural forms.

Unless otherwise specified, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Also, terms as defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the relevant technical description, and, unless expressly provided herein, interpreted in an ideal or overly formal sense It should not be.

Claims (15)

Is delimited by two parallel first side edges 4a and 4b and two parallel second side edges 6a and 6b and extends from the first end of the plate 2 to the first distribution portion (12a) adjacent to the first distribution portion (12a), a port hole (8b, 10b) adjacent to the second distribution portion (12b) at a second end of the plate (2) A plate heat exchanger plate (2) having a main heat transfer portion (14) including a pleated pattern between second distribution portions (12b)
The main heat transfer portion 14 includes a first region 16,
The first region (16)
A first field (30) having first corrugations arranged on one side of a straight first line (26) intersecting the second side edges (6a, 6b); A second field (32) having second pleats arranged on the opposite side of the first line (26); Extending parallel to the second side edges of the plate heat exchanger plate extending through the first field and the second field of the first region (16) of the main heat transfer portion (14) A straight line of < RTI ID = 0.0 >
The first corrugations include floors and grooves oriented at an angle between the first line (26) and an angle that is greater than 0 degrees and less than 90 degrees when measured in a clockwise or counterclockwise angular orientation , Said second corrugations comprising a floor plate (26) and a plate heat exchanger plate (26), said floor plate (26) having radii and troughs oriented at an angle between greater than 270 angles and less than 360 degrees when measured in said angular direction 2)
The main heat transfer portion 14 includes a first outer region 18 disposed between the first region 16 and a first second side edge 6a of the second side edges, Extending along the first second side edge (6a) between the first dispensing portion (12a) and the second dispensing portion (12b), wherein in the first outer region (18), the first side edges Characterized in that the first protrusions and recesses oriented in a first overall direction are arranged in relation to a second line (27) of a straight line parallel to the first side edge of one of the first, Heat exchanger plate (2). The method according to claim 1,
The main heat transfer portion 14 includes a first outer region 18 and a second outer region 18 disposed between the first region 16 and a second second side edge 6b of the second side edges, And extends along a second second side edge (6b) of the second side edges between the first distribution portion (12a) and the second distribution portion (12b) In the outer region 20, second projections and recesses oriented in a second overall direction with respect to the second line 27 are arranged
Plate Heat Exchanger Plate (2). 3. The method according to claim 1 or 2,
The first region (16) is arranged on one side of the first line (26) and is oriented at an angle between an angle greater than 90 and an angle less than 180 from the first line (26) in the angular direction And a third field (34) having third corrugations comprising grooves; and a third field (34) arranged on the opposite side of the first line (26) and having an angle greater than 180 and less than 270 from the first line And a fourth field (36) having fourth corrugations comprising angles and grooves oriented at an angle between angles
Plate Heat Exchanger Plate (2). 3. The method according to claim 1 or 2,
The floor and grooves of the first corrugations are oriented at an angle between greater than 45 and less than 90 degrees with the first line (26) when measured in the angular direction, and the floor and grooves of the second corrugations Are oriented at an angle between the first line (26) and an angle greater than 270 and less than 315 when measured in the angular direction
Plate Heat Exchanger Plate (2). The method of claim 3,
The floorings and grooves of the third corrugations are oriented at an angle between the first line (26) and an angle greater than 90 and less than 135 degrees when measured in the angular direction, and the floorings and / The grooves are oriented at an angle between the first line (26) and an angle greater than 225 and less than 270 degrees when measured in the angular direction
Plate Heat Exchanger Plate (2). 3. The method of claim 2,
Both the first overall direction, or the first overall direction and the second overall direction include at least one angle between angles of greater than 0 degrees and less than 90 degrees relative to the second line (27) doing
Plate Heat Exchanger Plate (2). 7. The method according to claim 2 or 6,
Both of the first outer region 18, the second outer region 20 or the first outer region 18 and the second outer region 20 are measured parallel to the second line 27 , Which is narrower than the first field (30) measured parallel to the second line (27)
Plate Heat Exchanger Plate (2). 7. The method according to claim 2 or 6,
Wherein the first protrusion, the second protrusion, or the first protrusion in the first outer region (18), the second outer region (20), or both the first outer region (18) And the second projections and the recesses include corrugations and grooved corrugations
Plate Heat Exchanger Plate (2). 9. The method of claim 8,
In the first and second outer regions (18, 20), when measuring across the floors and grooves, the floors have different widths from the grooves
Plate Heat Exchanger Plate (2). 7. The method according to claim 2 or 6,
The first projections and recesses are oriented in a first direction relative to the second line 27 or the second projections and recesses are oriented in a second direction relative to the second line 27, Or the first projections and recesses are oriented in a first direction with respect to the second line 27 and the second projections and recesses are directed in a second direction with respect to the second line 27, Oriented toward
Plate Heat Exchanger Plate (2). 7. The method according to any one of claims 1, 2, and 6,
The first side edges 4a and 4b are short sides of the plate 2 and the second side edges 6a and 6b are long sides of the plate 2,
Plate Heat Exchanger Plate (2). 7. The method according to claim 2 or 6,
Both the first outer region 18, the second outer region 20, or both the first outer region 18 and the second outer region 20 are formed by two or more fields 22a, 22b, 22c, 24a , 24b, and 24c
Plate Heat Exchanger Plate (2). A heat exchanger comprising a plate package (40) of plate heat exchanger plates (2) according to any one of claims 1, 2 and 6
Plate heat exchanger (50). 14. The method of claim 13,
The plate heat exchanger plates 2 are arranged in the plate package 40 so that the first outer region 18 of the one plate 2 contacts the second outer region 20 of the contact plate 2. [ Alternately arranged in the
Plate heat exchanger (50). 14. The method of claim 13,
Is configured for a parallel flow of at least two heat exchange fluids across the main heat transfer portion (14) of the plates (2) in the plate package (40)
Plate heat exchanger (50).

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